KR20160070762A - Plate for heat exchanger and heat exchanger - Google Patents

Abstract

Plate (1) for heat exchanger between the first medium and the second medium has inlet and outlet port holes (2a, 2b) for the first medium and inlet and outlet port holes (3a, 3b) for the second medium And having a first heat transfer surface (A) for the first medium and an opposite second heat transfer surface (B) for the second medium. The first heat transfer surface (A) Is formed with at least one barrier (5) forming part of a guide for the flow of the first medium as it passes between the inlet and outlet port holes (2a, 2b) for the medium, said plate (1) The method of claim 1, wherein the first media is transported during passage of the first medium between the portholes, around the inlet port hole (3a) for the second medium or around the inlet and outlet port holes (3a, 3b) U-shaped or sinusoidal through-flow ducts for first media to allow passage 2b and 3a, 3b for the first medium and the second medium, respectively, disposed on the first heat transfer surface to enable the formation of the first heat transfer surface X. Heat exchange The air cooler includes the above-described heat exchanger.

Description

PLATE FOR HEAT EXCHANGER AND HEAT EXCHANGER

The present invention relates to a plate for a heat exchanger for heat exchange between a first medium and a second medium. The plate is formed with inlet and outlet port holes for the first medium and inlet and outlet port holes for the second medium. The plate is also formed with a first heat transfer surface for the first medium and an opposite second heat transfer surface for the second medium.

The present invention also relates to a heat exchanger for heat exchange between a first medium and a second medium. The heat exchanger includes a stack of the above-described plates.

Finally, the invention relates to an air cooler comprising a heat exchanger as described above comprising a stack of the above-described plates.

BACKGROUND OF THE INVENTION [0002] Heat exchangers are used in a variety of areas, such as in the food processing industry, in buildings that use air conditioning systems, gas turbines, boilers, and the like. Attempts to improve the heat exchange capacity of the heat exchanger are always a concern, even small improvements are highly appreciated.

It is an object of the present invention to provide a heat exchanger plate and heat exchanger for improved guidance of a heat exchange medium in order to improve the cooling of one of the media and the heat exchange capacity.

These and other objects are achieved by providing a method of forming at least one barrier defining a portion of a guide for flow of a first medium as the first heat transfer surface of the plate passes between the inlet and outlet port holes for the first medium And wherein the plate is positioned between the inlet and outlet port holes for the first medium during passage of the first medium and around the inlet port hole for the second medium or between the inlet and outlet port holes for the first medium, A first medium disposed on the first heat transfer surface of the plate and a second medium disposed on the first heat transfer surface of the plate to enable formation of a substantially U- or sinusoidal through-flow duct for the first medium, A bar formed with an inlet and an outlet porthole for each of the media and a barrier defining a portion of the guide for the flow of the first media It is achieved by the rate.

Thus, in the condition that the first medium is a cooling medium and the second medium is a medium to be cooled, the plate is cooled by cooling of the second medium in which the first medium is to be immediately cooled at the inlet port hole for the second medium, Thereby improving the heat exchange. With at least one barrier forming a guide for the flow of the first medium, the plate is also formed to enable the first medium to be in extended contact with the second medium for cooling of the second medium . Finally, the plate may be formed to enable the first medium to cool the second medium also at the exit port holes for the second medium. By forming the plate such that the pores for the second medium are arranged in the middle of the flow of the first medium which can be controlled by the position of the at least one barrier forming part of the guide for the first medium, an optimal cooling of the second medium for reducing the thermal tension is achieved. Therefore, it is possible to use this plate in a heat exchanger for hot gas.

Facing each other in the circumferential portions of the portholes, in the circumferential portions of the portholes, and in the inlet and outlet port holes for the first medium on the first heat transfer surface of the plate, By forming a plate with dimples disposed at greater spacings relative to each other at portions remote from the first medium, the first medium can be used in a counter-flow type heat exchanger, The cooling of the second medium in the portholes can be further improved. This means that due to these dimples, the flow of the first medium is subjected to greater resistance at the portion of the circumference of the outlet port hole for the second medium facing the inlet port hole for the first medium, One more piece of media will be forced to flow further around the porthole for the second medium to cool the porthole and the second medium flowing through the porthole. In the inlet port hole for the second medium, the flow of the first medium undergoes a smaller resistance, and a larger portion of the first medium than it does not, before the first medium reaches its outlet port hole, It will reach the circumference of the inlet port hole for the second medium much more quickly to cool the port hole and the second medium flowing through the port hole.

Optimal guidance of the second medium for cooling the second medium is provided around the inlet and outlet portholes for the second medium on the second heat transfer surface of the plate, But also the dimples being spaced apart from one another in portions that are farther from each other and at least partially opposed to the inlet and outlet port holes for the first medium. The flow of the second medium will undergo a greater resistance in the mutually opposing portions of the circumferential portions of the portholes due to these dimples, whereby a greater portion of the flow of the second medium from the inlet port hole for the second medium Will initially flow in a direction away from the exit port holes for the second medium to force it to diffuse over the second heat transfer surface to be exposed to the first medium for cooling.

Optimal guidance of the second medium for cooling the second medium may also be achieved by at least one of forming at least one portion of the restraining portion against the flow of the second medium during passage of the second medium between the inlet and outlet port holes for the second medium Is achieved by forming a second heat transfer surface of the plate with the ridges. During passage of the second medium between the inlet and outlet port holes for the second medium, when the flow of the second medium reaches the ridge, it enables the suppression and deflection of at least part of the flow of the second medium By placing the ridges in the center of the second heat transfer surface of the plate, a substantial portion of the flow of the second medium can be directed to flow to the sides of the second heat transfer surface, whereby the flow distance and hence the second medium Thereby extending the time it takes to flow between the inlet and outlet port holes for the second medium along the second heat transfer surface.

These and other objects are achieved by providing a method of making two adjacent heat transfer surfaces for a first medium of two adjacent plates face each other and a second heat transfer surface for a second medium of two adjacent plates facing each other, With at least one barrier on the first heat transfer surface, a substantially U-shaped or sinusoidal through-flow duct for the first medium between the first heat transfer surfaces, and a through-flow duct for the second medium between the second heat transfer surfaces And the outer flanges on one of the two adjacent plates with which the first or second heat transfer surfaces face each other are stacked so that the plates are stacked so as to surround the through flow duct defined between the heat transfer surfaces ≪ / RTI >

A heat exchanger is provided as is limited and its heat exchange capacity is enhanced by optimal guidance of the first medium and the second medium for optimal cooling of the second medium.

As limited, the heat exchanger may be used, for example, to provide an improved air cooler. That is, one medium is air and the other medium is liquid.

The invention will be described in more detail below with reference to the accompanying drawings, which are briefly described herein.
1 is a plan view of a first embodiment of a plate according to the present invention.
2 is a perspective view of a first embodiment of a plate according to the present invention.
3 is a perspective view of the opposite side of the first embodiment of the plate according to the invention.
Fig. 4 is an enlarged perspective view of a part of the plate according to Fig. 2;
5 is a plan view of a second embodiment of the plate according to the present invention.
6 is a perspective view of a second embodiment of the plate according to the present invention.
7 is an opposite perspective view of a second embodiment of the plate according to the invention.
8 is an enlarged perspective view of a part of the plate according to Fig.
Figures 9a and 9b show a very schematic top view, similar to Figure 5, which is a second embodiment of the plate according to the invention, with most of the dimples removed for illustrative purposes, and the center of the plate shown in Figure 9a Fig.
Figs. 10A-10C are schematic cross-sectional views similar to Fig. 9B when assembled of a portion of two or three plates according to the present invention.

As described above, the present invention relates to a plate for a heat exchanger for heat exchange between a first medium and a second medium. The plate 1 may have a predetermined shape for its intended purpose. The plate 1 may be a rectangle having two opposed long sides 1a and 1b and two opposed short sides 1c and 1d as shown in the figure. The plate 1 may optionally have four equal length sides or any other suitable quadrangular, triangular, polyhedral, circular, rhombic, elliptical or other shape for intended applications and applications. A plurality of plates 1 may be assembled to form a stack for use in the heat exchanger according to the present invention.

The first and second media referred to in heat exchange may be the same as, for example, a gas / gas (such as air) or a liquid / liquid (such as water). The first and second media referred to may be two different media, for example gas / liquid, two different gases or two different liquids.

1-8 and 9a, the plate 1 according to the invention comprises at least one inlet port hole 2a and at least one outlet port hole 2b for the first medium and at least one inlet port hole 2b for the second medium, One inlet port hole 3a and at least one outlet port hole 3b. The inlet and outlet port holes 2a, 2b, 3a, and 3b for the first and second media are circular as shown in FIGS. 1-8 and 9a, but may of course have other suitable shapes for the intended application and application have. The diameters of the inlet and outlet port holes 3a and 3b for the second medium are equal to each other and much larger than the substantially same diameter of the inlet and outlet port holes 2a and 2b for the first medium. As shown in Figures 1-8 and 9a, as the plate 1 is rectangular, the inlet and outlet port holes 2a, 2b for the first medium are formed at both ends of the plate, for example two opposing Are disposed on the short sides 1c and 1d. The inlet and outlet port holes 3a and 3b for the second medium are also disposed at both ends of the plate 1 adjacent to or close to the inlet and outlet port holes 2a and 2b for the first medium. Thus, when the first and second media flow between their respective inlet and outlet port holes, their flow direction will generally be in the longitudinal direction of the plate as viewed, Increases the dwell time of the medium in each of the through-flow ducts (X, Y) and thereby improves the heat exchange capacity of the heat exchanger. When the heat exchanger comprising a plurality of such plates 1 is a counter-flow type, the inlet port hole 3a for the second medium is arranged close to the outlet port hole 2b for the first medium, The outlet port hole 3b for the second medium is disposed close to the inlet port hole 2a for the first medium. On the other hand, if the heat exchanger is a parallel-flow type, the inlet port hole 3a for the second medium is disposed close to the inlet port hole 2a for the first medium, (3b) is disposed close to the outlet port hole (2b) for the first medium. The plate 1 according to Figs. 1-8 is formed for use in a counter flow heat exchanger.

The plate 1 according to the present invention also comprises a first heat transfer surface A for the first medium as shown in Figures 1, 2, 4 and 7 and a second heat transfer surface A for the first medium as shown in Figures 3, 5, 6, 8 and 9a Has an opposite second heat transfer surface B for the second medium as shown in Fig. The inlet and outlet port holes 2a and 2b for the first medium are formed with the outer peripheral edges 2aa and 2ba respectively on the second heat transfer surface B and the inlet and outlet port holes 3a and 3b for the second medium And 3b are formed on the first heat transfer surface A with outer peripheral edges 3aa and 3ba, respectively. When the plate 1 is stacked, the plates are stacked such that the first heat transfer surface A for the first medium of two adjacent plates face each other (see FIGS. 10A and 10C). Then the outer peripheral edges 3aa and 3ba of the inlet and outlet port holes 3a and 3b for the second medium are in contact with each other so that the two first heat transfer surfaces A Through duct X defined between the through-flow duct X and the through-flow duct X. Correspondingly, when the plates 1 are stacked, the plates are stacked such that the second heat transfer surfaces B for the second medium of two adjacent plates face each other (see Figures 10b and 10c). Then the outer peripheral edges 2aa and 2ba of the inlet and outlet port holes 2a and 2b for the first medium come into contact with each other so that the two first heat transfer surfaces B for the second medium, To the penetrating flow duct (Y) defined between the through-flow ducts (Y).

The plate 1 according to the invention comprises an outer flange 4 protruding from the plate to surround one or both of the first heat transfer surface A for the first medium and the second heat transfer surface B for the second medium, As shown in FIG. 1-4, the flange 4 protrudes from the plate 1 to surround the second heat transfer surface B for the second medium, and in the embodiment of Figs. 5-8 and 9a , The flange 4 projects to surround the first heat transfer surface A for the first medium. In all other respects, the embodiment of the plate 1 shown in Figs. 5-8 and 9a is the same as the embodiment of the plate 1 shown in Figs. 1-4.

The first heat transfer surface A of the plate 1 according to the present invention also has a guide for the flow of the first medium when the first medium passes between the inlet and outlet port holes 2a and 2b for the first medium, I.e. at least one barrier 5 forming part of a guide arranged in a through-flow duct X for the first medium. Each barrier 5 may define a corresponding recess 5a on the second heat transfer surface B opposite the plate 1. [

According to the invention, the plate (1) is arranged such that during the passage of said first medium between the inlet and outlet port holes (2a, 2b) for said first medium when a plurality of plates are assembled to form a stack, A substantially U-shaped or sinusoidal curve for the first medium to enable passage of the flow of the first medium about the inlet port hole (3a) for the second medium or around the inlet and outlet port holes (3a, 3b) (2a, 2b and 3a, 3b) for each of the first medium and the second medium arranged with respect to each other to enable the formation of a through-flow duct (X) Is formed with a barrier (5) forming part of a guide for flow. Thus, the plate 1 is arranged between the inlet and outlet port holes 2a, 2b and 3a, 3b for each of the first medium and the second medium, i.e. between the two ends of the plate on which the said port holes are arranged, And a barrier (5) forming part of a guide for the flow of the medium, wherein one portal (2a, 3b) for each medium is located on one side of the barrier, and the other portal (2b, 3a) are located on the other side of the barrier.

As described above, the plate 1 is thus arranged such that the first medium, that is the cooling medium, forms at least one barrier (not shown) forming a guide for the flow of the first medium directly from the inlet port hole 3a for the second medium 5) is configured to enable cooling of the second medium to be cooled and heat exchange with the second medium to be improved, and the plate (1) is also configured to allow the first medium to be cooled 2 media to be in an extended contact state. Finally, the configuration of the plate may enable the first medium to cool the second medium also in the outlet port hole 3b for the second medium. The inlet port hole 3a for the second medium or both inlet and outlet port holes 3a and 3b can be controlled by the position of the at least one barrier 5 forming part of the guide for the first medium By forming the plate 1 so as to be arranged in the middle of the flow of the one medium, the optimum cooling of the second medium is achieved, making it possible to use the plate in a hot gas heat exchanger.

The plate 1 is defined as an inlet port hole 3a for the second medium or a through flow duct for the first medium as defined for guiding the flow of the first medium past the inlet and outlet port holes 3a, 2b and 3a and 3b for each of the first and second media for each other to enable the formation of the barrier 5 and the barrier 5, . ≪ / RTI >

According to the embodiments of the plate according to Figs. 1-8 and 9a, according to the rectangular plate 1 having two opposed long sides 1a and 1b and two opposing short sides 1c and 1d, A first medium placed in a corner or close to a corner between one of the long sides 1a or 1b (here, the long side 1a) and one of the two short sides 1c or 1d (here short side 1c) And an inlet port hole 2a. The outlet port hole 2b for the first medium is disposed in the corner or near the corner between the same long side 1a and the other one (1d or 1c) of the two short sides, that is, the short side 1d. The inlet port hole 3a for the second medium has one of two short sides 1c or 1d (for example, at a substantial center between two long sides 1a and 1b as shown) between two long sides 1a and 1b (Here, the plate 1 is regarded as being used in a heat exchanger of a cross-flow / counter-flow type, it is arranged close to the short side 1d), and the outlet The port hole 3b is disposed close to the other one of the two short sides (1d or 1c, i.e., the short side 1c) between the two long sides (e.g., at a substantial center between the two long sides). Optionally, in some embodiments in which the plate 1 has a smaller width, the inlet and outlet port holes 3a, 3b for the second medium are most likely to be the most intimate for the inlet and outlet port holes 2a, 2b for the first medium (In this case, the long side 1b) opposite to the near long side, and therefore, in the corner between the long side and each short side opposite to the corner where the entrance and exit port holes for the first medium are respectively disposed, . The plate 1 is also formed with three barriers 5 provided on the first heat transfer surface A of the plate. However, the number of barriers may be any other odd number, such as, for example, 1, 5, 7, 9, Two barriers 5 closest to the inlet and outlet port holes 2a and 2b for the first medium are formed so as to extend from the longest side 1a closest to the portholes toward the long side 1b opposite to each other, The third barrier between the first barrier and the second barrier is formed from the opposite long side 1b to the long side 1b so as to form a part of three guides for guiding the flow of the first medium along the substantially sinusoidal through- . If only one barrier 5 is provided on the first heat exchanging surface A of the plate 1, the barrier is provided with one guide for guiding the first medium along the substantially U- And extend from the longest side 1a closest to the portholes 2a and 2b toward the long side 1b facing the portholes 2a and 2b. According to the five, seven, nine or any other odd barrier (5), the barrier between the two barriers placed closest to the inlet and outlet port holes (2a, 2b) for the first medium is two long sides (1a or 1b) to the opposed long side (1b or 1a), whereby the additional guides for guiding the first medium along the substantially sinusoidal through-flow duct (X) Lt; / RTI > If, optionally, the plate 1 described above is formed with an even number of barriers 5, the barriers must be arranged so that at least the inlet port holes for the second medium and the second medium entering through it are cooled by the first medium do.

In one alternative embodiment, the plate 1 still has one of the two long sides 1a or 1b (e.g., the long side 1a) and one of the two short sides 1c or 1d (e.g., the short side 1c ) Or an inlet port hole (2a) for a first medium disposed in a corner or near a corner. However, the outlet port hole 2b for the first medium is formed in the corner between the other one (1b or 1a) of the two long sides, that is, the long side 1b and the other one (1d or 1c) Or close to the corner. This is shown by the broken lines in Figs. 1 and 5. The inlet port hole 3a for the second medium is formed between two long sides 1a and 1b (for example, as shown in Fig. 1-8 and 9a) between two long sides 1a and 1b One of the two short sides 1c or 1d (in this case also at the substantial center) (here again the plate 1 is considered to be used for a cross flow / counter flow heat exchanger, An outlet port hole 3b for the medium is disposed close to one of the two short sides (1d or 1c, i.e., the short side 1c) between the two long sides (e.g., at a substantial center between the two long sides). Here again, as described above, the inlet and outlet port holes 3a, 3b for the second medium are closer to the longest side facing the longest side closest to the inlet and outlet port holes 2a, 2b for the first medium, And may be disposed in or close to a corner between the long side and each short side of the opposite side of the corner where the inlet and outlet port holes for the first medium are disposed, respectively. Unlike the embodiments of Figs. 1-8 and 9a, the plate 1 here has an even number of barriers 5 on the first heat transfer surface A of the plate because of the position of the exit port hole 2b for the first medium I.e., two, four, six, eight, or more barriers. The two closest closest to the inlet and outlet port holes 2a, 2b for the first medium are respectively two guides 5 for guiding the flow of the first medium along the substantially sinusoidal through flow duct X, (1a or 1b) closest to each of the portholes (2a or 2b) to form a part of the pore (2a or 2b). According to the four, six, eight or any other even number of barriers 5, the barriers between the two barriers placed closest to the inlet and outlet port holes 2a, 2b for the first medium are two long sides (1a or 1b) to the opposed long side (1b or 1a), whereby the additional guides for guiding the first medium along the substantially sinusoidal through-flow duct (X) Lt; / RTI > If, optionally, the above-described plate 1 is formed with an odd barrier 5 as shown in Figs. 1-8 and 9a, the barriers will have at least an inlet port hole for the second medium and a second The medium must be arranged to be cooled by the first medium.

Thus, by forming the plate 1 with an arbitrary number of additional barriers 5, the first heat transfer surfaces A for the first medium of the two adjacent plates are combined and are formed by the barriers when facing each other The through flow duct X for the first medium to be defined by the guides to be extended will be extended to extend the time for heat exchange between the first medium and the second medium to improve the heat exchange capacity.

Each barrier 5 between the closest closures to the inlet and outlet port holes 2a and 2b for the first medium preferably extends from each long side 1a or 1b where they begin to extend to a small gap 6 ). This results in a leakage of a portion of the flow of the first medium through the space or through the space defined by the two said gaps that face each other when the first heat transfer surface (A) for the first medium of the two adjacent plates are merged . With such a configuration of the plate 1, it is possible to deflect a small amount of the first medium so as to increase the flow of the first medium along a part of the long sides 1a and 1b of the plate 1b.

Each of the barriers 5 preferably extends substantially perpendicularly to its long side from each of the long sides 1a and 1b, though the angle may change.

Optionally, the barrier 5 may be provided on one or both of the short sides 1c (1c) of the plate to form a portion of the one or more guides which, of course, allows the formation of a substantially U- or sinusoidal through- (1d) for the second medium, and wherein during the passage of the first medium between the inlet and outlet port holes (2a, 2b) for the first medium the inlet port hole (3a) or the inlet port port It is also possible to form the plate 1 having the inlet and outlet port holes 2a, 2b, 3a, 3b for the first and second media arranged so as to allow the flow of the first medium around the first and second media (3a, 3b) Do.

In order to save space for heat exchange between the first medium and the second medium, each barrier 5 is stretched in the illustrated embodiments of the plate 1 to a length several times larger than the width I have. In the illustrated embodiments of the plate 1, each barrier 5 also has the same height h1, i.e. the outer periphery of the inlet and outlet port holes 3a, 3b for the second medium on the first heat transfer surface A, And have heights that match or substantially match the heights of the edges 3aa, 3ba. However, the heights of the barriers 5 of the different plates 1 may differ as well as the heights of the outer peripheral edges 3aa and 3ba on the different plates may be different.

The inlet and outlet port holes 3a and 3b for the second medium are disposed substantially at the center between the two long sides 1a and 1b of the plate 1 or the inlet and outlet port holes 2a and 2b for the first medium, The inlet and outlet port holes 3a and 3b for the second medium are also located nearest to the nearest short side 1c or 1d (not shown), as in the illustrated embodiments, ) And the closest barrier 5, as shown in Fig. Whereby a uniform flow of the first medium around the portholes 3a, 3b for the second medium is achieved.

In the illustrated embodiments of the plate according to the invention, the second heat transfer surface B of the plate 1 is in contact with the flow of the second medium during the passage of the second medium between the inlet and outlet port holes 3a, 3b And at least one ridge (7) forming part of the restraining portion. The ridge 7 is thus arranged between the inlet and outlet port holes 3a, 3b for the second medium. Thus, in the illustrated embodiments of the plate 1, the ridges 7 are arranged such that during passage of said second medium between said inlet and outlet port holes 3a, 3b for a second medium, Corresponding to the barrier (5) on the first heat transfer surface (A), so as to enable suppression and deflection of at least a part of the flow of the second medium when the flow of the medium reaches the ridge (7) (B) between the first heat transfer surface (5a) and the second heat transfer surface (B). If desired, there may be more than one ridge 7, each ridge having a predetermined extension for its intended application or use. A substantial portion of the flow of the second medium can be directed to flow to the side surfaces of the second heat transfer surface by the ridges 7 as shown, whereby the flow distance and hence the second medium, 3b for the second medium along the path (B) of the first medium. Each ridge 7 may define a corresponding depression 7a on the first heat transfer surface A opposite the plate 1. [

The first heat transfer surface A of the plate 1 and the second heat transfer surface B opposite thereto are each formed with pressure-resistant turbulent flow generating dimples 9, 10 and 11, 12, respectively. The dimples 9, 10, 11, 12, which may have a predetermined shape based on the intended application and use, also define the height of the through-flow ducts X, Y for the first and second media, respectively Participate. The dimples 9 and 10 on the first heat transfer surface A have a height which is greater than the height of the dimples 11 and 12 on the opposite second heat transfer surface B so that the throughflow duct X for the first medium Is larger than the volume of the through-flow duct (Y) for the second medium. The dimples 9 outside the depressions 7a of the first heat transfer surface A are formed by at least a part of the barrier 5 or a barrier not within the scope of the depression in accordance with the embodiments shown, Has the same or substantially the same height h1 as the outer peripheral edges 3aa and 3ba of the inlet and outlet port holes 3a and 3b for the second medium on the first heat transfer surface A. The dimple 10 in the depression 7a of the first heat transfer surface A has a height h2 that is larger than the height h1 of the other dimples 9 outside the depression. The height h2 of the dimple 10 in the depression 7a of the first heat transfer surface A is equal to or substantially equal to the height of the portion of the barrier 5 that does not fall within the range of the depression in accordance with the illustrated embodiments And is equal to or substantially equal to the height of the dimple 9 plus the depth of the depression. The depression 7a defines a portion of the through-flow duct X for the first medium having a height 2h2 greater than the height 2h1 of the through-flow duct outside the depression. The dimples 11 on the ridge 7 of the second heat transfer surface B have a height h3 which is smaller than the height h4 of the other dimples 12 on the second heat exchange surface. The height of the ridge 7 plus the height of the dimples 11 on the ridge is the same or substantially the same as the height h4 of the other dimples 12 on the second heat transfer surface B. The height h4 of the dimples 12 outside the ridge 7 is also equal to the height h4 of the outer peripheral edges 2aa and 2b of the inlet and outlet port holes 2a and 2b for the first medium on the second heat transfer surface B of the plate 1. [ , 2ba, respectively. The ridge 7 defines a portion of the through-flow duct (Y) for the second medium having a height (2h3) that is less than the height (2h4) of the through-flow duct outside the ridge, Provides a restraining portion for causing a portion of the flow of the medium to flow to both sides of the second heat transfer surface (B).

According to the invention, the plate 1 is formed with an additional dimple 13 around the inlet and outlet port holes 3a, 3b for the second medium on the first heat transfer surface A of the plate. These dimples 13 are arranged at larger intervals with respect to each other in the mutually opposing portions of the circumferential portions of the portholes 3a and 3b than the mutually distant portions of the circumferential portions of the portholes 3a and 3b. As described above, the plate 1 is provided with the dimples 13 as defined, and at the same time the larger dimples are arranged substantially distant from the inlet and outlet port holes 2a, 2b for the first medium By being formed, the first medium may further improve the cooling of the second medium in the portholes for the second medium. This causes the dimples 13 to undergo a greater resistance at the portion where the flow of the first medium is facing the inlet port hole 2a for the first medium in the circumference of the outlet port hole 3b for the second medium , Wherein a greater portion of the first medium than it does not reach the outlet port hole for cooling the second medium flowing through the outlet port hole and the outlet port hole, Because it will be forced to flow farther around. In the inlet port hole 3a for the second medium, the flow of the first medium undergoes a smaller resistance, so that a greater portion of the first medium than it does not, Prior to reaching the inlet port hole and reaching the circumferential portion of the inlet port hole for the second medium much more quickly to cool the inlet port hole and the second medium flowing through the inlet port hole. The dimples 13 around the inlet and outlet port holes 3a and 3b for the second medium on the first heat transfer surface A of the plate 1 are identical or substantially equal to the height h1 of the dimples 9, Can have a height.

The above-described arrangement of the dimples 13 around the inlet and outlet port holes 3a, 3b for the second medium on the first heat transfer surface A of the plate is considered to be used for the heat exchanger of the counter flow type Especially when it is effective. In the cocurrent type heat exchanger, the arrangement of the dimples 13 may be the same.

The plate 1 is formed in such a way with an additional dimple 14 around the inlet and outlet port holes 3a, 3b for the second medium on the second heat transfer surface B of the plate. These dimples 14 are arranged at a greater distance from each other in the portions farther from each other in the circumferential portions of the portholes 3a and 3b than the portions facing each other in the circumferential portions of the portholes 3a and 3b. Optimal guidance of the second medium for cooling the second medium is achieved by the fact that the plate 1 has the dimples 14 as defined and at the same time the dimples which are more widely spaced apart form the inlet and outlet port holes 2a And 2b, which are formed at least partially opposite to each other. This is because the second medium undergoes less constrained flow toward the inlet and outlet port holes for the first medium for cooling the entire flow path of the second medium from the inlet port hole to the outlet port hole for the second medium. The dimples 14 around the inlet and outlet port holes 3a and 3b for the second medium on the second heat transfer surface B of the plate 1 may be the same or substantially the same as the height h4 of the dimples 12, Can have a height.

All the dimples 9, 10, 11, 12, 13 and 14 have depressions 9a, 10a, 11a, 12a, 13a and 14a corresponding to the opposite side of the plate 1.

Finally, each plate 1 may also be formed with at least one (two in the illustrated embodiments) portholes 15a, 15b. In the illustrated embodiments, the other side of each of the inlet and outlet port holes 3a, 3b for the second medium, which is disposed at the opposite corners of the inlet and outlet port holes 2a, 2b for the first medium These relatively small portholes 15a and 15b on the first heat transfer surface A are each surrounded by the outer peripheral edges 15aa and 15ba on the first heat transfer surface A to prevent the first medium from entering the portholes. On the one hand, the portholes 15a, 15b can communicate with the through-flow ducts Y for the second medium defined between the second heat transfer surfaces of the two adjacent plates 1 on the second heat transfer surface B . The second medium cooled by the first medium is condensed and accumulated on the second heat transfer surface (B) while passing through the through-flow duct (Y) for the second medium, flows into the portholes (15a, 15b) Through the portholes 15a, 15b by appropriate positioning of the portholes 15a, 15b.

As described above, the present invention also relates to a heat exchanger for heat exchange between the first medium and the second medium. The heat exchanger comprises a stack of plates 1 of the above-described construction. The stack of plates 1 can be arranged in a substantially open framework and a pipe connection for the first and second media is also provided. Depending on the intended application or use, the number of plates 1 in the stack can be varied and the dimensions of the heat exchanger can also be varied.

As already mentioned above, the plate 1 in the stack of heat exchangers has a first heat exchanging surface A for each of the plates in the first medium (e.g. water for cooling the second medium) (See Figs. 10A and 10C), by virtue of the opposing barrier 5, a substantially U-shaped or sinusoidal penetration for the first medium between the first heat transfer surfaces of the plates Are arranged to define the flow duct (X). Opposing peripheral edges 3aa and 3ba around the opposed dimples 9,10 and 13 and the inlet and outlet port holes 3a and 3b for the second medium are of course also provided with a through-flow duct X for the first medium And the opposed peripheral edges 15aa, 15ba around the portholes 15a, 15b for the discharge of the condensed second medium naturally also define the through-flow duct X for the first medium for some time But the shape of the through-flow duct X for the first medium is determined by the barrier 5. Thus, during the operation of the heat exchanger including the stack of plates 1 described above, the first medium is a heat exchanger of a countercurrent type, having a first heat transfer surface A (for a first medium of two adjacent plates 1) ) Can pass around two opposing outlet port holes 3b for the second medium before they can pass through the guide defined by the opposing barriers 5 on the first medium 1, The medium must pass around two additional opposed inlet port holes (3a) for the second medium before leaving the through-flow duct (X). In a cocurrent heat exchanger, before the first medium can pass through the guide defined by the opposing barrier 5 on the first heat transfer surface A for the first medium of two adjacent plates 1, Must pass around two opposing inlet port holes (3a) for the second medium and, after passing through the guide, the first medium has to pass through two additional opposed inlet port holes (3a) for the second medium before leaving the through- Through the outlet port hole 3b.

The plate 1 also has a second heat exchange surface B for a second medium (e.g., air cooled by water) of each plate in contact with a second heat transfer surface B of an adjacent plate in the stack, (See Figures 10B and 10C) to define a through flow duct (Y) for a second medium between the second heat transfer surfaces of the plates. The opposed peripheral edges 2aa and 2ba around the opposed dimples 11 and 12 and the inlet and outlet port holes 2a and 2b for the first medium are of course the through ducts Y for the second medium Contributes to the limitation.

The second medium flows along the through-flow duct (Y), preferably in a cross flow for the first medium. That is, the heat exchanger according to the invention preferably has a substantially U-shaped or sinusoidal through-flow duct (X) for the first medium defined between the first heat transfer surfaces (A) of two adjacent plates in the stack Parallel or substantially parallel portions extend in a first direction D1 of the plate perpendicular or substantially perpendicular to the longitudinal direction of the plate in the illustrated embodiments and the second heat transfer surface of the two adjacent plates in the stack B of the plate is perpendicular or substantially perpendicular to the longitudinal direction of the plate or substantially perpendicular to the longitudinal direction of the plate in the illustrated embodiments, Direction and extends in the direction D2. 10a-c, the through-flow ducts X for the first medium extend in a first direction D1 perpendicular to the plane defined by the plane of the drawing, and the through-flow ducts for the second medium Y extend in a plane defined by the plane of the drawing. Further, as described above, the second medium enters through the inlet port hole 3a for the second medium into its through-flow duct and leaves the through-flow duct through its outlet port hole 3b. That is, the second medium flows in the opposite direction to the flow of the first medium between the inlet and outlet port holes (2a, 2b) for the first medium in the illustrated embodiments of the plate (1). However, the heat exchanger according to the present invention may also optionally be of another type that is not of the crossover / countercurrent type, for example, as described above, for example, the second medium is passed through the inlet port hole 3a for the second medium, When the second medium enters the duct and leaves the through-flow duct through its outlet port hole 3b, the second medium flows in the same direction as the flow of the first medium between the inlet port holes 2a, 2b for the first medium May be of the cocurrent type. In any case, even if the second medium does not flow through both of the portholes 3a and 3b for the second medium and at least the second medium enters the heat exchanger through the inlet port hole for the second medium, It is important.

The plate 1 also has a through-flow duct (X or Y) in which an outer flange on the plate of one of two adjacent plates facing the first or second heat transfer surface A or B is defined between the heat transfer surfaces And stacked to surround. This outer flange may be the outer flange 4, as described above. The outer flange 4 may protrude from the plate 1 to surround both the first heat transfer surface A for the first medium of the plate and the second heat transfer surface B for the second medium. Then, only every second plate in the stack needs to be formed with an outer peripheral flange. Alternatively, the outer flange 4 may protrude from every second plate to surround only the second heat transfer surface B for the second medium (see Figs. 1-4 and 10a-c) (See Figs. 5-8, 9a-9b and 10a-c) to surround only the first heat transfer surface A (see Figs. 5-8, 9a-9b and 10a-c). Then, it is necessary that each plate 1 in the stack is formed with an outer peripheral flange.

In a barrier 5 in which the first heat transfer surface A for the first medium of the two adjacent plates in the stack is opposed to each other in the opposed dimples 9, 10 and 13 in order to provide a pressure- And facing outer peripheral edges 3aa and 3ba surrounding the inlet and outlet port holes 3a and 3b for the second medium and the second and third media 1 and 2 for the second medium of the two adjacent plates 1 in the stack, The heat exchange surface B is suitably assembled at the opposed peripheral edges 2aa and 2ba surrounding the inlet and outlet port holes 2a and 2b for the first medium and at the opposed dimples 11,

The outer peripheral flange 4 surrounding the plate 1 is also provided with an adjacent plate and / or another outer peripheral flange (not shown) to provide a secure first and second medium flow without sufficient leakage through the respective through-flow ducts X, It needs to be assembled properly.

While the invention has been illustrated by the description of preferred embodiments and while these embodiments have been described in considerable detail, it is not the intention of the applicant to limit or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will be apparent to those skilled in the art. Therefore, the invention is not limited to the specific details, representative apparatus, method and illustrative embodiment shown and described in the broader aspects. Accordingly, modifications from such details can be made without departing from the scope of the inventive concept of the generic invention. It is also to be understood that improvements and / or modifications may be made without departing from the scope of the invention, which is defined by the following claims. Thus, particularly the plate 1 is made of stainless steel, but may also be made of any other suitable material. The stack of plates in the heat exchanger may be disposed within a framework of any suitable material. The heat exchanger, at its intended application, can be arranged at any suitable position, i.e. horizontally, vertically or obliquely as required. A heat exchanger as defined may be suitable for use as an air cooler, since the second medium which is the medium to be cooled may be air.

Claims (25)

A plate for a heat exchanger for heat exchange between a first medium and a second medium,
The plate 1 comprises at least one inlet port hole 2a for the first medium and at least one outlet port hole 2b and at least one inlet port hole 3a for the second medium and at least one outlet port hole 3b ),
The plate (1) has a first heat transfer surface (A) for a first medium and an opposite second heat transfer surface (B) for a second medium,
The first heat transfer surface (A) of the plate (1) forms a portion of the guide for the flow of the first medium during passage of the first medium between the inlet and outlet port holes (2a, 2b) for the first medium At least one barrier (5)
Characterized in that the plate (1) is arranged in the middle of the passage of the first medium between the inlet and outlet port holes (2a, 2b) for the first medium, around the inlet port hole (3a) To allow the formation of a substantially U-shaped or sinusoidal through-flow duct (X) for the first medium to enable passage of the flow of said first medium around the portholes (3a, 3b) (2a, 2b and 3a, 3b) for each of a first medium and a second medium disposed on the surface (A) relative to one another and a guide for the flow of the first medium And a barrier (5). The method according to claim 1,
The plate (1) is formed with inlet and outlet port holes (2a, 2b) for a first medium disposed at both ends of the plate,
The plate 1 is formed at both ends of the plate with inlet and outlet port holes 3a and 3b for a second medium disposed adjacent the inlet and outlet port holes 2a and 2b for the first medium And,
Characterized in that the plate (1) is formed with a barrier (5) forming part of a guide for the flow of the first medium disposed between both ends of the plate. 3. The method of claim 2,
The plate 1 has a rectangular shape having two opposed long sides 1a and 1b and two opposed short sides 1c and 1d,
The plate 1 has an inlet port hole 2a for a first medium placed in a corner or near a corner between one of the two long sides 1a or 1b and one of the two short sides 1c or 1d, And an outlet port hole (2b) for a first medium disposed in a corner or near a corner between the long side (1a or 1b) and the other one (1d or 1c) of the two short sides,
The plate 1 has an inlet port hole 3a and two long sides 1a and 1b for a second medium disposed close to one of the two short sides 1c or 1d between the two long sides 1a and 1b, And an outlet port hole (3b) for a second medium disposed adjacent to the other one of the two short sides (1d or 1c) between the two short sides,
The plate (1) is formed with an odd barrier (5) provided on a first heat transfer surface (A) of the plate,
The barrier 5 closest to the inlet and outlet port holes 2a and 2b for the first medium is formed so as to extend from the long side 1a or 1b closest to the portholes toward the long side 1b or 1a facing the first port, And forms a portion of one or more guides for guiding the flow of said first medium along a U-shaped or sinusoidal through-flow duct (X). 3. The method of claim 2,
The plate 1 has a rectangular shape having two opposed long sides 1a and 1b and two opposed short sides 1c and 1d,
The plate 1 has an inlet port hole 2a for a first medium disposed in a corner or close to a corner between one of the two long sides 1a or 1b and one of the two short sides 1c or 1d, An outlet port hole 2b for a first medium disposed in a corner or close to a corner between the other one of the two long sides (1b or 1a) and the other one of the two short sides (1d or 1c) ,
The plate 1 has an inlet port hole 3a and two long sides 1a and 1b for a second medium disposed close to one of the two short sides 1c or 1d between the two long sides 1a and 1b, And an outlet port hole (3b) for a second medium disposed adjacent to the other one of the two short sides (1d or 1c) between the two short sides,
The plate (1) is formed with an even number of barriers (5) provided on a first heat transfer surface (A) of the plate,
The barrier 5 closest to the inlet and outlet port holes 2a and 2b for the first medium is formed to extend from the long side 1a or 1b closest to each port hole to the opposite long side 1b or 1a, To form a portion of guides for guiding the flow of said first medium along a sinusoidal through-flow duct (X). The method of claim 3,
The plate 1 is formed with one additional barrier 5 between two barriers 5 located closest to the inlet and outlet port holes 2a and 2b for the first medium,
The additional barrier 5 is opposite from the opposite long side 1b or 1a of the long side 1a or 1b where the barrier 5 closest to the inlet and outlet port holes 2a and 2b for the first medium begins to extend Is formed to extend toward the long side (1a or 1b) to form a part of guides for guiding the flow of the first medium along the substantially sinusoidal through-flow duct (X). The method according to claim 3 or 4,
The plate 1 is formed with at least two additional barriers 5 between two barriers 5 located closest to the inlet and outlet port holes 2a and 2b for the first medium,
The additional barrier 5 is formed to alternately extend from one of the two long sides 1a or 1b toward the opposite long side 1b or 1a so as to extend along the substantially sinusoidal through- RTI ID = 0.0 > 1, < / RTI > The method according to claim 5 or 6,
The additional barrier 5 is formed by a small gap 6 from each long side 1a or 1b from which the additional barrier 5 begins to extend so that a portion of the flow of the first medium through the gap And permitting an exit. 8. The method according to any one of claims 1 to 7,
Characterized in that each barrier (5) has the same height (h1). 9. The method according to any one of claims 1 to 8,
The second heat transfer surface (B) of the plate (1) has at least one ridge (3b) which forms part of the restraining portion against the flow of the second medium during passage of the second medium between the inlet and outlet port holes 7). ≪ / RTI > 10. The method of claim 9,
The plate 1 is formed with ridges 7 disposed between the inlet and outlet port holes 3a and 3b for the second medium on the second heat transfer surface B of the plate, During the flow of the second medium between the inlet and outlet port holes (3a, 3b) for the second medium, when the flow of the second medium reaches the ridge, it is possible to suppress and deflect at least a part of the flow of the second medium Of the plate. 11. The method according to any one of claims 1 to 10,
The first heat transfer surface A of the plate 1 and the second heat transfer surface B of the opposite side are all connected to the dimple (X, Y) which will define the heights of the through-flow ducts X, Y for the first and second media, 9, 10 and 11, 12, respectively,
The dimples 9 and 10 on the first heat transfer surface A have a height h1 and h2 greater than the heights h3 and h4 of the dimples 11 and 12 on the opposite second heat transfer surface B Features a plate. 12. The method of claim 11,
The first heat transfer surface (A) of the plate (1) is formed with at least one depression (7a) corresponding or substantially corresponding to the ridge (7) on the second heat transfer surface (B) ,
Characterized in that the dimple (10) in the depression (7a) has a height (h2) greater than the height (h1) of the other dimples (9) on the first heat transfer surface (A). 13. The method according to claim 11 or 12,
Characterized in that the dimple (9) outside the depression (7a) of the first heat transfer surface (A) of the plate (1) has the same or substantially the same height (h1) as the barrier (5). 14. The method according to any one of claims 11 to 13,
The dimple 11 on the ridge 7 of the second heat transfer surface B of the plate 1 has a height h3 smaller than the height h4 of the other dimple 12 on the second heat exchange surface B, ). ≪ / RTI > 15. The method according to any one of claims 11 to 14,
The plate 1 is provided around the inlet and outlet port holes 3a and 3b for the second medium on the first heat transfer surface A of the plate at a distance from each other in the circumferential portion of the portholes 3a and 3b And dimples (13) arranged at larger intervals in mutually facing portions of the circumferential portions of the portholes (3a, 3b). 16. The method according to any one of claims 11 to 15,
The plate 1 is arranged around the inlet and outlet port holes 3a and 3b for the second medium on the second heat transfer surface B of the plate at a position facing each other in the circumferential portion of the portholes 3a and 3b And dimples (14) arranged at larger distances from each other at portions farther from each other in the circumferential portion of the portholes (3a, 3b). 17. The method according to any one of claims 1 to 16,
The inlet and outlet port holes 2a and 2b for the first medium are formed with the outer peripheral edges 2aa and 2ba on the second heat transfer surface B of the plate 1,
Characterized in that the inlet and outlet port holes (3a, 3b) for the second medium are formed with outer peripheral edges (3aa, 3ba) on the first heat transfer surface (A) of the plate (1). 18. The method of claim 17,
The outer peripheral edges 2aa and 2ba of the inlet and outlet port holes 2a and 2b for the first medium on the second heat transfer surface B of the plate 1 are connected to the ridges 7 on the second heat transfer surface B, Has the same or substantially the same height (h4) as the outer dimple (12)
The outer peripheral edges 3aa and 3ba of the inlet and outlet port holes 3a and 3b for the second medium on the first heat transfer surface A of the plate 1 are in contact with the barrier 5 on the first heat transfer surface A, Characterized in that it has the same or substantially the same height (h1) as the dimple (9). 19. The method according to any one of claims 1 to 18,
The plate 1 has an outer flange 4 protruding from the plate to surround one or both of a first heat transfer surface A for the first medium and a second heat transfer surface B for the second medium . The method according to any one of claims 1 to 19,
Characterized in that the plate (1) is formed with at least one porthole (15a and / or 15b) for enabling discharge of the second medium. A heat exchanger for heat exchange between a first medium and a second medium,
Said heat exchanger comprising a stack of plates (1) according to any one of claims 1 to 20,
The plate (1) comprises:
The first heat transfer surface A for the first medium of two adjacent plates 1 faces one another and the second heat transfer surface B for the second medium of two adjacent plates face one another, With at least one barrier (5) on the first heat transfer surface (A) of the plate, a substantially U-shaped or sinusoidal through-flow duct (X) for the first medium between the first heat transfer surfaces To define a through flow duct (Y) for a second medium between the second heat transfer surfaces (B), and
An outer flange 4 on one of two adjacent plates 1 facing the first or second heat transfer surface A or B faces a through flow duct (X or Y) defined between the heat transfer surfaces Wherein the heat exchanger is stacked to be enclosed. 22. The method of claim 21,
A first heat transfer surface A for the first medium of two adjacent plates 1 in the stack is formed in the opposing barrier 5 and dimples 9 and 10 and in the second heat transfer surface A Are assembled at opposing edges (3aa, 3ba) surrounding the inlet and outlet port holes (3a, 3b). 23. The method of claim 21 or 22,
A second heat exchange surface B for the second medium of two adjacent plates 1 in the stack is formed at the inlet and outlet for the first medium in the opposed dimples 11 and 12 and in the second heat transfer surface B, Are assembled at opposing edges (2aa, 2ba) surrounding the portholes (2a, 2b). 24. The method according to any one of claims 21 to 23,
Straight parallel or substantially parallel portions of a substantially U-shaped or sinusoidal through-flow duct (X) for a first medium defined between the first heat transfer surfaces (A) of two adjacent plates (1) Extends in a first direction (D1) of the plate,
A through-flow duct (Y) for a second medium defined between the second heat transfer surfaces (B) of two adjacent plates (1) in the stack is arranged perpendicular to the first direction And extends in two directions (D2). An air cooler comprising a heat exchanger according to any one of claims 21 to 24, wherein the first medium is liquid and the second medium is air.

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